-------------------------------------------------------------------------------------------
--
-- DIST MEM GEN Core - Stimulus Generator For Simple Dual Port RAM Configuration
--
-------------------------------------------------------------------------------------------
--
-- (c) Copyright 2006_3010 Xilinx, Inc. All rights reserved.
--
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-- of Xilinx, Inc. and is protected under U.S. and
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--------------------------------------------------------------------------------
--
-- Filename: qspi_data_info_64_mem_tb_stim_gen.vhd
--
-- Description:
--  Stimulus Generation For SIMPLE DUAL PORT RAM
--
--------------------------------------------------------------------------------
-- Author: IP Solutions Division
--
-- History: Sep 12, 2011 - First Release
--------------------------------------------------------------------------------
--
--------------------------------------------------------------------------------
-- Library Declarations
--------------------------------------------------------------------------------
LIBRARY IEEE;
USE IEEE.STD_LOGIC_1164.ALL;
USE IEEE.STD_LOGIC_ARITH.ALL;
USE IEEE.STD_LOGIC_UNSIGNED.ALL;
USE IEEE.STD_LOGIC_MISC.ALL;

LIBRARY work;
USE work.ALL;

USE work.qspi_data_info_64_mem_TB_PKG.ALL;


ENTITY REGISTER_LOGIC_SDRAM IS
  PORT(
    Q   : OUT STD_LOGIC;
    CLK : IN STD_LOGIC;
    RST : IN STD_LOGIC;
    D   : IN STD_LOGIC
  );
END REGISTER_LOGIC_SDRAM;

ARCHITECTURE REGISTER_ARCH OF REGISTER_LOGIC_SDRAM IS
  SIGNAL Q_O : STD_LOGIC :='0';
BEGIN
  Q <= Q_O;
  FF_BEH: PROCESS(CLK)
  BEGIN
    IF(RISING_EDGE(CLK)) THEN
      IF(RST ='1') THEN
     	  Q_O <= '0';
      ELSE
        Q_O <= D;
      END IF;
    END IF;
  END PROCESS;
END REGISTER_ARCH;

LIBRARY IEEE;
USE IEEE.STD_LOGIC_1164.ALL;
USE IEEE.STD_LOGIC_ARITH.ALL;
USE IEEE.STD_LOGIC_UNSIGNED.ALL;
USE IEEE.STD_LOGIC_MISC.ALL;

LIBRARY work;
USE work.ALL;
USE work.qspi_data_info_64_mem_TB_PKG.ALL;

ENTITY qspi_data_info_64_mem_TB_STIM_GEN IS
   PORT(
     CLK : IN STD_LOGIC;
     RST : IN STD_LOGIC;
     A   : OUT  STD_LOGIC_VECTOR(6-1 downto 0)   := (OTHERS => '0'); 
     D   : OUT  STD_LOGIC_VECTOR(64-1 downto 0)        := (OTHERS => '0');
     DPRA : OUT  STD_LOGIC_VECTOR(6-1 downto 0)   := (OTHERS => '0');
     WE         : OUT  STD_LOGIC  := '0';
     DATA_IN : IN STD_LOGIC_VECTOR (63 DOWNTO 0);   --OUTPUT VECTOR 
        
     CHECK_DATA : OUT STD_LOGIC:='0'
    	  );
END qspi_data_info_64_mem_TB_STIM_GEN;

ARCHITECTURE BEHAVIORAL OF qspi_data_info_64_mem_TB_STIM_GEN IS
  CONSTANT ZERO           : STD_LOGIC_VECTOR(31 DOWNTO 0)                := (OTHERS => '0');
  CONSTANT DATA_PART_CNT_A: INTEGER:=1;
  SIGNAL   WRITE_ADDR     : STD_LOGIC_VECTOR(31 DOWNTO 0)                := (OTHERS => '0');
  SIGNAL   WRITE_ADDR_INT : STD_LOGIC_VECTOR(5 DOWNTO 0)   := (OTHERS => '0');
  SIGNAL   READ_ADDR_INT  : STD_LOGIC_VECTOR(5 DOWNTO 0)   := (OTHERS => '0');
  SIGNAL   READ_ADDR      : STD_LOGIC_VECTOR(31 DOWNTO 0)                := (OTHERS => '0');
  SIGNAL   D_INT          : STD_LOGIC_VECTOR(63 DOWNTO 0) := (OTHERS => '0');
  SIGNAL   DO_READ_REG    : STD_LOGIC_VECTOR(4 DOWNTO 0) :=(OTHERS => '0');
  SIGNAL   DO_WRITE       : STD_LOGIC                                    := '0';
  SIGNAL   DO_READ        : STD_LOGIC                                    := '0';

  SIGNAL   PORTA_WR                : STD_LOGIC:='0';
  SIGNAL   COUNT                   : INTEGER :=0;
  SIGNAL   INCR_WR_CNT             : STD_LOGIC:='0';
  SIGNAL   PORTA_WR_COMPLETE       : STD_LOGIC :='0';
  SIGNAL   PORTB_RD                : STD_LOGIC:='0';
  SIGNAL   COUNT_RD                : INTEGER :=0;
  SIGNAL   INCR_RD_CNT             : STD_LOGIC:='0';
  SIGNAL   PORTB_RD_COMPLETE       : STD_LOGIC :='0';
  SIGNAL   LATCH_PORTA_WR_COMPLETE : STD_LOGIC :='0';
  SIGNAL   PORTB_RD_HAPPENED       : STD_LOGIC := '0';
  SIGNAL   PORTA_WR_L1             :STD_LOGIC  := '0';
  SIGNAL   PORTA_WR_L2             :STD_LOGIC  := '0';
  SIGNAL   PORTB_RD_R2             :STD_LOGIC  := '0';
  SIGNAL   PORTB_RD_R1             :STD_LOGIC  := '0';
  SIGNAL   LATCH_PORTB_RD_COMPLETE : STD_LOGIC :='0';
  SIGNAL   PORTA_WR_HAPPENED       : STD_LOGIC := '0';
  SIGNAL   PORTB_RD_L1             : STD_LOGIC  := '0';
  SIGNAL   PORTB_RD_L2             : STD_LOGIC  := '0';
  SIGNAL   PORTA_WR_R2             : STD_LOGIC  := '0';
  SIGNAL   PORTA_WR_R1             : STD_LOGIC  := '0';
  
  CONSTANT WR_RD_DEEP_COUNT :INTEGER :=8;
  CONSTANT WR_DEEP_COUNT    : INTEGER := WR_RD_DEEP_COUNT;
  CONSTANT RD_DEEP_COUNT    : INTEGER := WR_RD_DEEP_COUNT;

BEGIN
  WRITE_ADDR_INT(5 DOWNTO 0) <= WRITE_ADDR(5 DOWNTO 0);
  READ_ADDR_INT(5 DOWNTO 0)  <= READ_ADDR(5 DOWNTO 0);
  A <= WRITE_ADDR_INT; 
  D <= D_INT;
  DPRA <= READ_ADDR_INT;
  CHECK_DATA <= DO_READ;


  RD_AGEN_INST:ENTITY work.qspi_data_info_64_mem_TB_AGEN
    GENERIC MAP(
      C_MAX_DEPTH => 64 
    )
    PORT MAP(
      CLK        => CLK,
      RST        => RST,
      EN         => DO_READ,
      LOAD       => '0',
   	LOAD_VALUE => ZERO,
      ADDR_OUT   => READ_ADDR
    );

  WR_AGEN_INST:ENTITY work.qspi_data_info_64_mem_TB_AGEN
    GENERIC MAP( 
      C_MAX_DEPTH => 64    )
    PORT MAP(
      CLK        => CLK,
      RST        => RST,
  	   EN         => DO_WRITE,
      LOAD       => '0',
      LOAD_VALUE => ZERO,
  	   ADDR_OUT   => WRITE_ADDR
      );

  WR_DGEN_INST:ENTITY work.qspi_data_info_64_mem_TB_DGEN 
    GENERIC MAP ( 
      DATA_GEN_WIDTH => 64,
      DOUT_WIDTH     => 64 ,
      DATA_PART_CNT  => DATA_PART_CNT_A,
      SEED           => 2)
    PORT MAP (
      CLK      => CLK,
	   RST       => RST,
      EN       => DO_WRITE,
      DATA_OUT => D_INT          
    );

  PORTA_WR_PROCESS: PROCESS(CLK)
  BEGIN
    IF(RISING_EDGE(CLK)) THEN
      IF(RST='1') THEN
        PORTA_WR<='1';
      ELSE
        PORTA_WR<=PORTB_RD_COMPLETE;
      END IF;
    END IF;
  END PROCESS;

  PORTB_RD_PROCESS: PROCESS(CLK)
  BEGIN
    IF(RISING_EDGE(CLK)) THEN
      IF(RST='1') THEN
        PORTB_RD<='0';
      ELSE
        PORTB_RD<=PORTA_WR_L2;
      END IF;
    END IF;
  END PROCESS;

  PORTB_RD_COMPLETE_LATCH: PROCESS(CLK) 
    BEGIN
    IF(RISING_EDGE(CLK)) THEN
      IF(RST='1') THEN
        LATCH_PORTB_RD_COMPLETE<='0';
      ELSIF(PORTB_RD_COMPLETE='1') THEN
        LATCH_PORTB_RD_COMPLETE <='1';
      ELSIF(PORTA_WR_HAPPENED='1') THEN
        LATCH_PORTB_RD_COMPLETE<='0';
      END IF;
    END IF;
  END PROCESS;
  
  PROCESS(CLK)
  BEGIN
    IF(RISING_EDGE(CLK)) THEN
      IF(RST='1') THEN
        PORTB_RD_L1 <='0';
        PORTB_RD_L2 <='0';
      ELSE
       PORTB_RD_L1 <= LATCH_PORTB_RD_COMPLETE;
       PORTB_RD_L2 <= PORTB_RD_L1;
      END IF;
   END IF;
  END PROCESS;
  
  PROCESS(CLK)
  BEGIN
    IF(RISING_EDGE(CLK)) THEN
      IF(RST='1') THEN
        PORTA_WR_R1 <='0';
        PORTA_WR_R2 <='0';
      ELSE
       PORTA_WR_R1 <= PORTA_WR;
       PORTA_WR_R2 <= PORTA_WR_R1;
      END IF;
   END IF;
  END PROCESS;
  
  PORTA_WR_HAPPENED <= PORTA_WR_R2;
  
  PORTA_WR_COMPLETE_LATCH: PROCESS(CLK) 
    BEGIN
    IF(RISING_EDGE(CLK)) THEN
      IF(RST='1') THEN
        LATCH_PORTA_WR_COMPLETE<='0';
      ELSIF(PORTA_WR_COMPLETE='1') THEN
        LATCH_PORTA_WR_COMPLETE <='1';
      ELSIF(PORTB_RD_HAPPENED='1') THEN
        LATCH_PORTA_WR_COMPLETE<='0';
      END IF;
    END IF;
  END PROCESS;
  
  PROCESS(CLK)
  BEGIN
    IF(RISING_EDGE(CLK)) THEN
      IF(RST='1') THEN
        PORTA_WR_L1 <='0';
        PORTA_WR_L2 <='0';
      ELSE
        PORTA_WR_L1 <= LATCH_PORTA_WR_COMPLETE;
        PORTA_WR_L2 <= PORTA_WR_L1;
      END IF;
   END IF;
  END PROCESS;
  
  PROCESS(CLK)
  BEGIN
    IF(RISING_EDGE(CLK)) THEN
      IF(RST='1') THEN
        PORTB_RD_R1 <='0';
        PORTB_RD_R2 <='0';
      ELSE
        PORTB_RD_R1 <= PORTB_RD;
        PORTB_RD_R2 <= PORTB_RD_R1;
      END IF;
   END IF;
  END PROCESS;
  
  PORTB_RD_HAPPENED <= PORTB_RD_R2;
  
  PORTB_RD_COMPLETE <= '1' when (count_rd=RD_DEEP_COUNT) else '0';
  
  start_rd_counter: process(CLK)
  begin
    if(rising_edge(CLK)) then
      if(RST='1') then
        incr_rd_cnt <= '0';
      elsif(portb_rd ='1') then
        incr_rd_cnt <='1';
      elsif(portb_rd_complete='1') then
        incr_rd_cnt <='0';
      end if;
    end if;
  end process;
  
  RD_COUNTER: process(CLK)
  begin
    if(rising_edge(CLK)) then
      if(RST='1') then
        count_rd <= 0;
      elsif(incr_rd_cnt='1') then
        count_rd<=count_rd+1;
      end if;
      --if(count_rd=(wr_rd_deep_count)) then
     if(count_rd=(RD_DEEP_COUNT)) then
        count_rd<=0;
      end if;
   end if;
  end process;
  
  DO_READ<='1' when (count_rd <RD_DEEP_COUNT and incr_rd_cnt='1') else '0';
  
  PORTA_WR_COMPLETE <= '1' when (count=WR_DEEP_COUNT) else '0';
  
  start_counter: process(CLK)
  begin
    if(rising_edge(CLK)) then
      if(RST='1') then
        incr_wr_cnt <= '0';
      elsif(porta_wr ='1') then
        incr_wr_cnt <='1';
      elsif(porta_wr_complete='1') then
        incr_wr_cnt <='0';
      end if;
    end if;
  end process;
  
  COUNTER: process(CLK)
  begin
    if(rising_edge(CLK)) then
      if(RST='1') then
        count <= 0;
      elsif(incr_wr_cnt='1') then
        count<=count+1;
      end if;
      if(count=(WR_DEEP_COUNT)) then
        count<=0;
      end if;
   end if;
  end process;
  
  DO_WRITE<='1' when (count <WR_DEEP_COUNT and incr_wr_cnt='1') else '0';

BEGIN_SHIFT_REG: FOR I IN 0 TO 4 GENERATE
BEGIN
  DFF_RIGHT: IF I=0 GENERATE
  BEGIN
    SHIFT_INST_0: ENTITY work.REGISTER_LOGIC_SDRAM
      PORT MAP(
        Q   => DO_READ_REG(0),
        CLK => CLK,
        RST => RST,
        D   => DO_READ
      );
  END GENERATE DFF_RIGHT;
  DFF_OTHERS: IF ((I>0) AND (I<=4)) GENERATE
  BEGIN
     SHIFT_INST: ENTITY work.REGISTER_LOGIC_SDRAM
       PORT MAP(
         Q   => DO_READ_REG(I),
         CLK => CLK,
         RST => RST,
         D   => DO_READ_REG(I-1)
       );
  END GENERATE DFF_OTHERS;
END GENERATE BEGIN_SHIFT_REG;


  WE <= IF_THEN_ELSE(DO_WRITE='1','1','0') ;

END ARCHITECTURE;
